Crystallization and preliminary X-ray analysis of PepC, a thiol aminopeptidase from Lactoccocus lactis homologous to bleomycin hydrolase

An evolutionarily conserved cysteine protease, human bleomycin hydrolase, binds to the human homologue of ubiquitin-conjugating enzyme 9

Bleomycin hydrolase (BH) is a highly conserved cysteine proteinase that deamidates and inactivates the anticancer drug bleomycin. Yeast BH self-assembles to form a homohexameric structure, which resembles a 20 S proteasome and may interact with other proteins. Therefore, we searched for potential human BH (hBH) partners using the yeast two-hybrid system with a HeLa cDNA library and identified the full-length human homologue of yeast ubiquitin-conjugating enzyme 9 (UBC9). Cotransformation assays using hBH deletion mutants revealed that the carboxyl terminus of hBH (amino acids 356-455), which contains two of the three essential catalytic amino acids, was not critical for protein binding in the yeast two-hybrid environment. In vitro translated human UBC9 was precipitated by glutathione S-transferase-hBH fusion protein but not by glutathione S-transferase. Efficient in vitro binding occurred in the absence of the first 24 amino acids of UBC9 and the catalytic Cys93 of UBC9. We confirmed that hBH and UBC9 interacted in vivo by affinity copurification of proteins overexpressed in mammalian cells. Using immunocytochemical analysis, hBH was colocalized with UBC9. Coexpression of hBH and UBC9 in mammalian cells did not markedly alter the bleomycin-hydrolyzing activity of hBH or apparent small ubiquitin-related modifier 1 addition. This is the first reported heteromeric interaction with hBH, and it suggests a role for hBH in intracellular protein processing and degradation.

Catalytic properties of the cysteine aminopeptidase PepC, a bacterial bleomycin hydrolase

PepC is a cytoplasmic thiol aminopeptidase widely conserved among lactic acid bacteria. PepC from Lactococcus lactis shares 35-38% identity with aminopeptidases of eukaryotic origins: the yeast and mammalian bleomycin hydrolases (BLMase). In this work we investigated the hydrolytic activity of PepC towards various substrates: bleomycin A2, aminoacyl-p-nitroanilides (pNA) and peptides. First, we found the bleomycin hydrolase activity of lactococcal PepC and measured similar kinetics parameters to those reported for the mammalian BLMase. Second, the results obtained on aminoacyl-pNA confirmed the capacity of the enzyme to release a broad range of amino acids and the pH activity profile suggests the presence of an ionic interaction between the enzyme and the free alpha-amino group of the substrate. Third, the aminopeptidase activity measured on peptide substrates revealed that PepC possesses an extended binding site which interacts with the peptidic backbone of the substrate. The hydrolytic efficiency is highly dependent on the length of the peptide, optimal for tetrapeptides and further enhanced by the presence of hydrophobic residues in the P' positions of the substrate. These enzymatic properties are of importance for the design of specific inhibitors and the biological function of the bleomycin hydrolases.

Experimental evidence for the essential role of the C-terminal residue in the strict aminopeptidase activity of the thiol aminopeptidase PepC, a bacterial bleomycin hydrolase

PepCs isolated from lactic acid bacteria and bleomycin hydrolases of eukaryotic organisms are strict aminopeptidases which belong to the papain family of thiol peptidases. The structural basis of the enzymic specificity of the lactococcal PepC has been investigated by site-directed mutagenesis. The deletion of the C-terminal residue (Ala-435) abolished the aminopeptidase activity, whereas this deletion led to a new peptidase specificity. The enzymic properties of wild-type and mutant PepCs demonstrate that the terminal alpha-carboxy group plays a key role in the strict aminopeptidase activity.

The proteolytic systems of lactic acid bacteria

Proteolysis in dairy lactic acid bacteria has been studied in great detail by genetic, biochemical and ultrastructural methods. From these studies the picture emerges that the proteolytic systems of lactococci and lactobacilli are remarkably similar in their components and mode of action. The proteolytic system consists of an extracellularly located serine-proteinase, transport systems specific for di-tripeptides and oligopeptides (> 3 residues), and a multitude of intracellular peptidases. This review describes the properties and regulation of individual components as well as studies that have led to identification of their cellular localization. Targeted mutational techniques developed in recent years have made it possible to investigate the role of individual and combinations of enzymes in vivo. Based on these results as well as in vitro studies of the enzymes and transporters, a model for the proteolytic pathway is proposed. The main features are: (i) proteinases have a broad specificity and are capable of releasing a large number of different oligopeptides, of which a large fraction falls in the range of 4 to 8 amino acid residues; (ii) oligopeptide transport is the main route for nitrogen entry into the cell; (iii) all peptidases are located intracellularly and concerted action of peptidases is required for complete degradation of accumulated peptides.

Cys102 and His398 are required for bleomycin-inactivating activity but not for hexamer formation of yeast bleomycin hydrolase

The bleomycin-inactivating enzyme, bleomycin hydrolase, is believed to be involved in tumor resistance to the anticancer drug bleomycin. This homohexamer is an aminopeptidase that shows homology to cysteine proteinases around the cysteine and histidine active site. The role that these residues play in hydrolyzing bleomycin and in hexamer oligomerization of bleomycin hydrolase is not known. In this study, the yeast bleomycin hydrolase gene was expressed in Escherichia coli, and site-directed mutagenesis was employed to precisely investigate the roles of the conserved Cys102 and His398 residues in its structure and enzymatic activity. Three mutants were created, in which Cys102 was replaced by arginine or serine, and His398 was changed to glycine. The ability of bleomycin hydrolase to oligomerize was neither affected by the subtle cysteine/serine mutation nor affected by cysteine/arginine or histidine/glycine mutations. However, the ability of bleomycin hydrolase to hydrolyze and inactivate bleomycin was totally abolished in all three mutants, suggesting that the cysteine thiol and histidine imidazole are critical for hydrolyzing bleomycin. Furthermore, in contrast to predictions from the recently reported crystal structure of this enzyme, hexamer formation is not required for the enzymatic activity of bleomycin hydrolase. Thus, these results demonstrate that Cys102 and His398 are required for bleomycin hydrolase activity but not hexamer formation, and that both monomer and hexamer are active forms of bleomycin hydrolase.

Bacterial aminopeptidases: properties and functions

Aminopeptidases are exopeptidases that selectively release N-terminal amino acid residues from polypeptides and proteins. Bacteria display several aminopeptidasic activities which may be localised in the cytoplasm, on membranes, associated with the cell envelope or secreted into the extracellular media. Studies on the bacterial aminopeptide system have been carried out over the past three decades and are significant in fundamental and biotechnological domains. At present, about one hundred bacterial aminopeptidases have been purified and biochemically studied. About forty genes encoding aminopeptidases have also been cloned and characterised. Recently, the three-dimensional structure of two aminopeptidases, the methionine aminopeptidase from Escherichia coli and the leucine aminopeptidase from Aeromonas proteolytica, have been elucidated by crystallographic studies. Most of the quoted studies demonstrate that bacterial aminopeptidases generally show Michaelis-Menten kinetics and can be placed into either of two categories based on their substrate specificity: broad or narrow. These enzymes can also be classified by another criterium based on their catalytic mechanism: metallo-, cysteine- and serine-aminopeptidases, the former type being predominant in bacteria. Aminopeptidases play a role in several important physiological processes. It is noteworthy that some of them take part in the catabolism of exogenously supplied peptides and are necessary for the final steps of protein turnover. In addition, they are involved in some specific functions, such as the cleavage of N-terminal methionine from newly synthesised peptide chains (methionine aminopeptidases), the stabilisation of multicopy ColE1 based plasmids (aminopeptidase A) and the pyroglutamyl aminopeptidase (Pcp) present in many bacteria and responsible for the cleavage of the N-terminal pyroglutamate.

Purification, crystallization, and preliminary X-ray analysis of PepX, an X-prolyl dipeptidyl aminopeptidase from Lactococcus lactis

The X-prolyl dipeptidyl aminopeptidase PepX, a serine peptidase isolated originally from Lactococcus lactis subsp lactis NCDO 763, was cloned and overproduced in Escherichia coli. The enzyme was isolated in its active form in two purification steps. Crystals of PepX were grown by the hanging drop vapor diffusion method using polyethyleneglycol 4000 as precipitant at pH 5.0. The crystals are orthorhombic with cell dimensions a = 92.8 A, b = 102.6 A, and c = 101.6 A, space group P2(1)2(1)2, and probably contain one monomer of 87.5 kDa in the asymmetric unit. The crystals, very stable under X-rays, diffract to at least 2.2 A and are suitable for high-resolution structural analysis.

Crystal structure of a conserved protease that binds DNA: the bleomycin hydrolase, Gal6

Bleomycin hydrolase is a cysteine protease that hydrolyzes the anticancer drug bleomycin. The homolog in yeast, Gal6, has recently been identified and found to bind DNA and to act as a repressor in the Gal4 regulatory system. The crystal structure of Gal6 at 2.2 A resolution reveals a hexameric structure with a prominent central channel. The papain-like active sites are situated within the central channel, in a manner resembling the organization of active sites in the proteasome. The Gal6 channel is lined with 60 lysine residues from the six subunits, suggesting a role in DNA binding. The carboxyl-terminal arm of Gal6 extends into the active site cleft and may serve a regulatory function. Rather than each residing in distinct, separable domains, the protease and DNA-binding activities appear structurally intertwined in the hexamer, implying a coupling of these two activities.

Cloning and nucleotide sequence analysis of the Lactobacillus delbrueckii ssp. lactis DSM7290 cysteine aminopeptidase gene pepC

A genomic library of Lactobacillus delbrueckii ssp. lactis DSM7290 in the low copy number vector pLG339, was screened for the presence of peptidase genes. Using the chromogenic substrate gly-ala-beta-naphthylamide, which is not a substrate for any of the recently cloned peptidases of DSM7290, and the multiple peptidase deficient Escherichia coli strain CM89, allowed the isolation of clones, which contained the equivalent hydrolytic activity. To identify genes encoding the conserved catalytic active site of cysteine proteases, partial nucleotide sequencing with a degenerate oligonucleotide was performed on recombinant plasmids isolated from such clones. This allowed to identify two out of nine clones to carry the Lactobacillus pepC gene. A total of 2026 nucleotides were determined, and sequence analysis revealed a gene with strong homology to the recently cloned Lb. helveticus (73.2%) and Lactococcus lactis (51.03%) pepC genes, and the derived protein showed homology with the active site of a large number of cysteine proteases. The predicted open reading frame consists of 449 codons, coding for a protein of 50,909 Da. The enzyme is functional and extremely overexpressed in E. coli.

Gene cloning and characterization of PepC, a cysteine aminopeptidase from Streptococcus thermophilus, with sequence similarity to the eucaryotic bleomycin hydrolase

Streptococcus thermophilus CNRZ 302 contains at least three general aminopeptidases able to hydrolyze Phe-beta-naphthylamide substrate. The gene encoding one of these aminopeptidases was cloned from a total DNA library of S. thermophilus CNRZ 302 constructed in Escherichia coli TG1 using pBluescript plasmid. The wild-type TG1 strain, although not deficient in aminopeptidase activity, is unable to hydrolyze the substrate Phe-beta-naphthylamide, and thus the library could be screened with an enzymic plate assay using this substrate. One clone was selected which was shown to express an aminopeptidase, identified as a PepC-like enzyme on the basis of cross-reactivity with polyclonal antibodies directed against the lactococcal PepC cysteine aminopeptidase. The gene was further subcloned and sequenced. A complete open reading frame coding for a 445-residue (50414 Da) polypeptide was identified. 70% identity was found between the deduced amino acid sequence and the sequence of PepC from Lactococcus lactis subspecies cremoris, confirming the identity of the cloned gene. High sequence similarity (38% identity) was also found with an eucaryotic enzyme, bleomycin hydrolase. In addition, the predicted amino acid sequence of the streptococcal PepC showed a region of strong similarity to the active site of cysteine proteinases with conservation of the residues involved in the catalytic site. The product of the cloned pepC gene was overproduced in E. coli and was purified from a cellular extract. Purification to homogeneity was achieved by two-step ion-exchange chromatography. Biochemical characterization of the pure recombinant enzyme confirms that the cloned peptidase is a thiol aminopeptidase possessing a broad specificity. The enzyme has a molecular mass of 300 kDa suggesting an hexameric structure. On the basis of sequence similarities as well as common biochemical and enzymic properties, the bacterial PepC-type enzymes and the eucaryotic bleomycin hydrolase constitute a new family of thiol aminopeptidases among the cysteine peptidases.